1.5 Machines and Computers on the Microscale and Nanoscale
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in muscle contraction. Other neurotransmitters are epinephrine and norepinephrine
(also called adrenalin and noradrenalin, respectively), which are both part of the fight-
or-flight response, dopamine and serotonin, which are part of mood regulation, as well
as histamine, γ-aminobutyric acid (GABA), glycine, glutamate, aspartate, and nitric
oxide (NO).
When an action potential arrives at the end of the axon and the calcium channel is
opened, the calcium does not only change the membrane potential but the ions them-
selves also bind to the proteins that hold the neurotransmitter vesicles to the cytoskele-
ton, thus releasing the vesicles. The vesicles now act like any small particle phase in a
matrix (here the solution). The vesicle membranes are hydrophobic, so with the release
of the vesicles there is suddenly a high amount of hydrophobic surface in the hydrophilic
solution of the nerve ending. To release that high-energy state, the vesicles move to and
merge into the synapse membrane. The vesicle and synapse membranes have very sim-
ilar compositions and can simply merge; this automatically releases their contents, the
neurotransmitter, into the synaptic cleft. The neurotransmitter then diffuses to the other
side, initiating the action potential in the dendrite, as discussed above.
This is the barebones description of what happens at a synapse. In reality, there
are many regulatory mechanisms going on at the same time using other ion channels
or transmembrane channels, also signal transduction pathways that modify the activity
of the synapse itself, directly or allosterically, all in the name of homeostasis as well as
analysis of the incoming data. Here, “analysis” also stands for higher-order thinking,
memory, and consciousness. Only a fraction of these details and processes are currently
fully understood.
1.5 Machines and Computers on the Microscale and Nanoscale
Machines on the microscale and nanoscale usually end up being based on computer
chips. Why is that and how do they work? Let us start with what they made from: semi-
conductors. In conductors, usually metals, valence electrons have the energy needed to
conduct, i. e., are in the conduction band (Figure 1.40).
When the conduction band is energetically somewhat removed from the energy
of the valence electrons, you have a semiconductor (Figure 1.40). You can get electrons
moving in semiconductors by heating them, to get them energetically into the conduc-
tion band. More commonly, voltage is used as energy. To increase the number of charges
that are conducted, semiconductors are usually doped.
The most common semiconductor material is silicon, which has a valence of 4. If
silicon is doped with atoms with a valence of 3 (e. g., boron) you create “electron holes”
and with that a p-type semiconductor. Doping with atoms of a valence of 5 (e. g., phos-
phorous) will result in an n-type semiconductor that is conducting electrons.
Many parts of electric circuits can be built from semiconductors. An important one
is the transistor. A transistor can be both a switch and an amplifier. An example of a